Andy Bechtolsheim (Arista Co-Founder) – The 400 Gigabit Landscape (Sep 2017)
Chapters
Abstract
The Evolution of Ethernet Port Speeds and Optical Networking Technologies: An Insight into the Future of Cloud Networks
Introduction
In the rapidly evolving field of Ethernet port speeds and optical technologies, a transformative shift is witnessed from conventional 10G lanes to advanced 100G and beyond. This article, grounded in the expert perspectives of Brad Booth and Tom Isenhut from Microsoft and the standards set by IEEE and other entities, delves into the intricacies of this transition. It examines the market’s move towards higher speed ports, challenges in standardization, silicon and optical lane matching, power consumption considerations, module-level implications, the evolution of form factors, and the physical and technical challenges ahead.
Ethernet Port Speeds: A Market in Transition
The landscape of Ethernet port speeds is undergoing a significant transformation. The popularity of 40G ports is waning, while 100G ports are rapidly gaining traction, expected to hit 10-12 million ports in the coming year. The 100G standard is the fastest growing Ethernet standard in terms of revenue growth. Meanwhile, the emergence of 400G ports marks a new era, though their adoption is tempered by higher costs. This shift is fueled by the growing demand for faster data transmission in cloud networks and data centers.
Optics in Cloud Networks: Current and Future Setups
Currently, cloud networks employ a setup involving 100 GHz with various cabling systems and optics types. This setup can be adapted for 400G by simply upgrading the speed per link by 4x. Such scalability is crucial for future-proofing cloud networks against ever-increasing data demands.
The Role of Standards: IEEE and MSA
The standardization of optics and Ethernet speeds is a complex process, often taking years to finalize. The IEEE standards have included specifications for 100GB DR and 400GB DR4, while the 100GB Lambda MSA addresses gaps in these standards, focusing on lower cost, power efficiency, and forwards compatibility.
Silicon and Optical Lane Synchronization
A key aspect of network technology evolution is the alignment of silicon lanes with optical lanes. This synchronization is essential to prevent speed bottlenecks and ensure efficient data transmission. The current and next generations of silicon are transitioning to higher lane speeds, paving the way for more efficient network configurations.
Power Consumption: A Crucial Consideration
In the world of networking, power consumption is a critical factor. The evolution from 25G silicon optics to more advanced configurations like 100G DR optics has significantly impacted power usage. These advancements allow for more power-efficient and cost-effective solutions, which are vital for sustainable technological growth.
Form Factor Evolution: OSFP vs. QSFP-DD
The development of form factors like OSFP and QSFP-DD represents a significant advancement in networking technology. These form factors, supporting high-density pluggable interfaces, are key to accommodating the growing demands of data centers. The competition between these two formats hinges on their thermal and electrical performance capabilities, especially at higher speeds.
Future Trends and Challenges
Looking ahead, the networking industry faces several challenges and opportunities. The adoption of DCOs (Digital Coherent Optics) and the development of new optics like DR4 and FR4 are on the horizon. Moreover, the industry must address the physical limitations of electrical interfaces and the challenges posed by current laser technologies.
Thermal Capabilities and Heat Management
In the field of optical interconnect technology, a key differentiator between QSFP and OSFP modules lies in their thermal capabilities. OSFP modules boast a 30-40% better thermal capability compared to their QSFP counterparts, making them ideal for applications involving Digital Coherent Optics (DCOs), which generate significant heat. This superior thermal performance is attributed to OSFP’s built-in heat sinks, eliminating the need for riding heat sinks and mitigating potential thermal gaps.
QSFP Interior Volume Limitations and Design Challenges
QSFP modules face limitations in terms of interior volume, hindering the integration of advanced optics. This constraint has led to the development of Type II QSFP modules, which extend 15 millimeters beyond Type I modules to accommodate larger optics. However, Type II modules lack heat sinks and controlled airflow outside the chassis, presenting thermal challenges and limiting their effectiveness in high-speed networking applications.
QSFP PDD’s Shortcomings and Long-Term Viability
Industry experts have raised concerns regarding the long-term viability of QSFP PDD (Parallel Detection Diodes) modules. Some experts view QSFP PDD as a limited solution with a short lifecycle, lacking the versatility and upgrade potential of successful form factors like SFP. Unlike SFP, which has undergone several upgrades from 1G to 50G and beyond, QSFP PDD’s limited upgrade path raises questions about its suitability for future networking needs.
QSRP’s Potential and Scaling Capabilities
QSRP (Quad Small Form-Factor Pluggable) modules, initially designed as 10G interfaces, have evolved to support higher speeds, including 40G and 100G. The potential of QSRP extends even further, with projections of scaling up to 200G and even 400G by 2020. This scalability makes QSRP a promising contender in the high-speed networking landscape.
OSFP’s Superior Density and Interface Options
OSFP modules offer superior density compared to QSFP modules, supporting either 2x400GB or 800GB interfaces. This versatility makes OSFP a suitable choice for data centers requiring high-bandwidth connectivity. In contrast, QSFP modules are limited to 8x50GB interfaces, restricting their capacity for high-speed data transmission.
Power Savings with 2×50 Optics and Forward Gearboxes
The transition to 2×50 optics, coupled with forward gearboxes, offers significant power savings compared to the traditional 4×25 approach. This power reduction translates to substantial energy savings, making 2×50 optics an attractive option for eco-conscious data centers and network operators.
AOC Cables, Fiber Requirements, and Infrastructure Upgrades
The adoption of 2×50 optics necessitates the use of new AOC (Active Optical Cables), copper cables, duplex and multimode fiber, and duplex single-mode fiber to replace the current optical setup. This infrastructure upgrade is essential to fully realize the benefits of 2×50 optics and ensure seamless high-speed data transmission.
In conclusion, the evolution of Ethernet port speeds and optical networking technologies is marked by rapid advancements and significant challenges. The industry’s ability to adapt to these changes will determine the future efficiency and scalability of cloud networks and data centers. As we forge ahead, it’s imperative to keep a close eye on these developments and their implications for the global digital infrastructure.
Notes by: crash_function